]]>https://neuronarrative.wordpress.com/2011/06/18/if-youre-looking-for-me/feed/0David DiSalvoJohn Cleese on Creativityhttps://neuronarrative.wordpress.com/2010/08/18/john-cleese-on-creativity/
https://neuronarrative.wordpress.com/2010/08/18/john-cleese-on-creativity/#commentsWed, 18 Aug 2010 18:40:27 +0000http://neuronarrative.wordpress.com/?p=4076]]>In this remarkable short talk, comic genius John Cleese explains what he has learned about the creative process. Be ready to take notes, because he passes along insights worth remembering every day.
]]>https://neuronarrative.wordpress.com/2010/08/18/john-cleese-on-creativity/feed/9David DiSalvoGoing Live on ‘Psychology Today’https://neuronarrative.wordpress.com/2010/08/16/going-live-on-psychology-today/
https://neuronarrative.wordpress.com/2010/08/16/going-live-on-psychology-today/#commentsMon, 16 Aug 2010 17:55:04 +0000http://neuronarrative.wordpress.com/?p=4070]]>

Wanted to let everyone know that Neuronarrative is now officially a Psychology Today blog, here. Please subscribe to the RSS feed for updates.

Best, David

]]>https://neuronarrative.wordpress.com/2010/08/16/going-live-on-psychology-today/feed/0David DiSalvologoBargaining with Monkeys Like Ushttps://neuronarrative.wordpress.com/2010/08/03/bargaining-with-monkeys-like-us/
https://neuronarrative.wordpress.com/2010/08/03/bargaining-with-monkeys-like-us/#commentsTue, 03 Aug 2010 15:06:28 +0000http://neuronarrative.wordpress.com/?p=4065Continue reading →]]>In this excellent TED talk, primatologist Laurie Santos discusses the roots of human irrationality by uncovering the way our primate relatives make decisions. Is it possible that the errors we make–like failing to save money–are not “mistakes” (in the conventional sense) but actually hardwired into our natures? Santos’ experiments in “monkeynomics” suggest answers to that question that might make human exceptionalists a little nervous.
]]>https://neuronarrative.wordpress.com/2010/08/03/bargaining-with-monkeys-like-us/feed/1David DiSalvoDid You See the Gorilla? An Interview with Psychologist Daniel Simonshttps://neuronarrative.wordpress.com/2010/07/27/did-you-see-the-gorilla-an-interview-with-psychologist-daniel-simons/
https://neuronarrative.wordpress.com/2010/07/27/did-you-see-the-gorilla-an-interview-with-psychologist-daniel-simons/#commentsTue, 27 Jul 2010 04:06:10 +0000http://neuronarrative.wordpress.com/?p=4040Continue reading →]]>

If you’ve spent any time on YouTube over the last few years (and you know you have), you’ve likely seen the video of the invisible gorilla experiment (if you’ve somehow missed it, catch yourself up here). The researchers who conducted that study, Dan Simons and Chris Chabris, didn’t realize that they were about to create an instant classic—a psychology study mentioned alongside the greats, and known well outside the slim confines of psych wonks. Milgram taught us about our sheepish obedience to authority; Mischel used marshmallows to teach us about delayed gratification; and Simons and Chabris used a faux gorilla to teach us that we are not the masters of attention we think we are.

The duo’s new book, The Invisible Gorilla, and Other Ways Our Intuitions Deceive Us, is every bit as engaging as the original study was innovative.Using the invisible gorilla study as a jumping off point, the authors go on to explain why so many of our intuitions are off the mark, though we’re typically convinced otherwise. I recently had a chance to chat with Dan Simons about the study, the book, and why we’re usually in the dark about how our minds really work.

DiSalvo: What gave you and Chris Chabris the idea for the invisible gorilla study?

Simons: Our study was actually based on some earlier research by Ulric Neisser conducted in the 1970s. His studies were designed to tease apart whether people focus attention on regions of space or on objects. He wanted to see whether, if people were focusing on one part of a scene, they would automatically notice if something unexpected passed through that “spotlight” of attention. To do that, he made all the objects partly transparent so that they all occupied the same space and could pass through each other. He found that people often missed an unexpected event. But, the strange, ghostly appearance of the displays gave people a ready excuse for why they missed the unexpected event. Oddly, no one followed up on those studies, so we thought we’d give them another look and see whether people would miss something that was fully visible and easy to see. We did our study as part of an undergraduate class project in a class that I was teaching.

Why the gorilla suit?

We were looking for something dramatic so that if people missed it, they would be surprised when we showed it to them again. We also wanted something that would have some humor value to it. Fortunately for us, Jerome Kagan, an eminent developmental psychologist at Harvard, happened to have one in his lab.

I remember the first time I watched the YouTube video of the study and was completely dumfounded when the question, “Did you see the gorilla?” flashed on the screen. As researchers, I can imagine getting that reaction from people is like hitting a home run.

It surprised us the first time we ran the study – we didn’t expect it to work as well as it did. It’s still a thrill to present the video to an audience and have people miss it. Our intuition that we’ll notice something as visible as a gorilla is a hard one to overcome. It took me years before I could trust that some people in almost any audience would miss it.

What do people tell you about their reaction afterwards?

Normally people can’t believe that they missed it. On occasion, they’ve accused us of switching the video. The intuition that we would notice makes it jarring for people to realize that they didn’t.

And that’s really the point, right, that we can’t know what we are missing until our attention is refocused on it?

That’s a big part of it. We can easily miss what’s right in front of us, but we don’t realize that we can. Part of the problem is that we’re only aware of the things we notice and we’re not aware of the things we didn’t notice. Consequently, we often have no idea what we’re missing.

Hence the myth of multi-tasking.

It depends on what you mean by multi-tasking. If you mean simultaneous attention shared across multiple tasks, then yes, it’s a myth. We typically cannot do two things simultaneously. We can perform multiple tasks one after another—a sort of serial tasking.

In the case of the first meaning, simultaneous attention across multiple tasks, why do you think so many of us are convinced we can do it?

I think a lot of people confuse these two possible ways of doing multiple tasks. Because we can do one task and then another, switching back and forth among them, we falsely believe we can do two at once. That confusion happens in part because we don’t realize how impaired we are when doing two things at once. We’re too distracted to notice that we’re distracted. That has dramatic consequences. For example, we can’t talk on the phone while driving because that requires doing two tasks at once rather than sequentially (and both require attention).

Where does the intuition originate?

Our intuitions are based on our experiences. The problem is that our daily experiences frequently support incorrect intuitions about how our minds work. We only are aware of the things we’ve noticed and we aren’t aware of the things we’ve missed, so we assume that we always notice things. We don’t notice when we’re distracted by multitasking, so we think we aren’t distracted. The same sort of principle explains many of our mistaken intuitions.

But why wouldn’t we develop an intuition from our experience that we can’t parse our attention?

Our experience is tied to our awareness. We are aware of what we notice, not of what we miss, so we develop an intuition based on noticing. The principle applies to multi-tasking: we are aware only that we are accomplishing multiple tasks, because our daily life demands it, but we aren’t aware that we’re not really doing them at the same time. As a result, we mistakenly assume that we can do two things at once. Given that we rarely encounter evidence to contradict our awareness — normally, there’s nobody around to point out the gorilla — we don’t learn when our intuitions are wrong.

We see people all the time who know very bad things can happen from, as one example, texting while driving, but they still do it.

That’s true, but most people could drive much of their lives without having an accident. And the longer they go without having an accident, the more they are deluded into thinking they can drive and text safely. Fortunately, accidents are rare, but when they happen, they are catastrophic. Knowing that we have these limits and taking them to heart can save our lives. We learn best from our own experiences, but in this case, you shouldn’t wait to experience the consequences of distracted driving for yourself.

I can’t help but notice how so much of what we’ve been discussing runs counter to the conclusions of one of the most popular non-fiction books out there: Malcolm Gladwell’s Blink. Many people I’ve talked to who have read that book are convinced that we should trust our instincts instead of thinking things through.

The idea that intuition, gut instincts, and rapid decisions are a panacea for all of our decision making problems is really dangerous. Unfortunately, that’s the message that some people have taken from Gladwell’s book. Intuitions can be quite useful for some types of decisions, especially those that involve an emotional preference —who do you find most attractive, what ice cream tastes best—but they can lead us dangerously wrong when they are based on assumptions about how our minds work. Gladwell is an incredible storyteller, but some of the conclusions he reaches in Blink are problematic. Our work, and the work of other cognitive scientists, shows again and again that the intuitions people hold about how their minds work are often wrong. When you dig deeper into the material he covers in Blink, you see that many of the featured examples are of expert pattern recognition, and that’s a very different thing than simply trusting intuition or instinct.

Like the example of a quarterback acting decisively without having time to think?

Yes, that’s expert pattern recognition. Peyton Manning studies films for many hours in preparation for each game, and he has done that for years. Then, in a game situation, he recognizes the pattern really quickly, and that leads him to find the open receiver readily. That said, even expert pattern recognition is far from perfect. If you let Manning analyze the films at a leisurely pace, he’ll find things he missed during the game. The same principle applies to most experts. They can make reasonably good decisions quickly and seemingly based on intuition — they’ll outperform novices with only a glance. But given more time, even the experts often would make better decisions.

Yet the takeaway for many people is that “thinking” is a hindrance.

Thinking takes work, and the idea that we could go with our gut and do better is really appealing. Unfortunately, it’s often not true.

What can we expect as a follow up from you guys? Can you top the gorilla study?

It’s hard to top having people miss a gorilla. I do have a new paper that just came out in the new open-access journal I-Perception. It talks about a new demonstration that I’ve called “The Monkey Business Illusion.” It’s on YouTube now. Basically, I wanted to see if people who knew about the original gorilla video would be immune to this sort of failure of awareness. Try it for yourself!

Simons, D. (2010). Monkeying around with the gorillas in our midst: familiarity with an inattentional-blindness task does not improve the detection of unexpected events i-Perception, 1 (1), 3-6 DOI: 10.1068/i0386

]]>https://neuronarrative.wordpress.com/2010/07/27/did-you-see-the-gorilla-an-interview-with-psychologist-daniel-simons/feed/11David DiSalvoSimons_11ResearchBlogging.orgLooking into the Mind of a Murdererhttps://neuronarrative.wordpress.com/2010/07/13/looking-into-the-mind-of-a-murderer/
https://neuronarrative.wordpress.com/2010/07/13/looking-into-the-mind-of-a-murderer/#commentsTue, 13 Jul 2010 17:41:49 +0000http://neuronarrative.wordpress.com/?p=4033Continue reading →]]>In the first video below, Dr. Jim Fallon discusses his studies of murderers’ brains and the surprising patterns that he has identified, including an overabundance of serotonin in utero for male children (turns out, being “bathed” in the so-called feel-good neurotransmitter isn’t a good thing). He also discusses an amazing family discovery that he stumbled upon while conducing his research.

The second and third videos are the first two parts of an absolutely chilling interview with the “Ice Man,” Richard Kuklinski, a mafia contract killer and perhaps the most prolific serial killer in U.S. history.

You’re standing at the Craps table and have already rolled a couple of times, losing money each time. You throw another roll, this time thankfully making back the money you lost.

Just then, from the corner of your eye, you notice that an attractive woman seems to be interested in your game (and perhaps you). You throw another roll and win again. You’re debating whether to quit while you’re ahead and cash out, but your concentration is broken by the woman who is now smiling at you and says, “You’re really doing great” as she reaches out and touches you gently on your back.

Not only do you decide to keep playing, but you significantly increase your bet. You lose, but she encourages you again with another touch, and you bet again.

What’s going on here? Are you simply so caught up in trying to impress this woman that you keep betting even though you’re in the hole? Perhaps. But according to a new study published in the journal Psychological Science, the reason might go deeper than that.

Participants were tested to see if they would take risks, such as investing money or making a substantial gamble. Before taking the risk, they were greeted in one of three different ways: (1) by a female or male researcher with a light touch on the shoulder, (2) a handshake, or (3) no physical contact at all. At the end of the experiment, participants filled out surveys that assessed how secure they felt.

The researchers found that participants who were touched on the shoulder felt more secure and took bigger risks than those who weren’t—but only if they were touched by a woman. The effect was stronger for a touch than for a handshake, but disappeared entirely for participants who were touched by a man.

The interesting part about this is that the same finding was found for men and women who were touched by a woman, suggesting that this is not solely a sexual attraction effect.

The researchers draw a line between this finding to previous research on how a woman’s touch affects an infant, making the child feel more secure and comfortable. It’s entirely possible that a woman’s touch works the same on adults—making them feel more secure and willing to take risks.

Which brings us back to the casino scenario. What do you think are the chances that the woman in question works for the casino and is planted in the crowd to make sure guys like you keep playing?

]]>https://neuronarrative.wordpress.com/2010/06/23/how-a-womans-touch-can-make-you-risk-it-all/feed/4David DiSalvowomantouchAsk, Don’t Tell, and Get it Donehttps://neuronarrative.wordpress.com/2010/06/07/ask-dont-tell-and-get-it-done/
https://neuronarrative.wordpress.com/2010/06/07/ask-dont-tell-and-get-it-done/#commentsMon, 07 Jun 2010 18:40:17 +0000http://neuronarrative.wordpress.com/?p=3905Continue reading →]]>Are you the sort of person who routinely tells yourself that you probably can’t achieve whatever it is you’d like to achieve? Does the voice in your head say things like, “Be realistic, you can’t really do this.” And perhaps, fed up with positive self-talk mumbo jumbo in the media, you think that the only self-talk worth listening to is the “realistic” kind—the kind that tells you how it is.

Well, whatever your feelings about positive psychology and its many spin-offs, there is some decent research with something to say about all of this—and your little voice should be listening. Research by University of Illinois Professor Dolores Albarracin and her team has shown that those who ask themselves whether they will perform a task generally do better than those who tell themselves that they will.

But first, a slight digression. If you have young kids or even early teens (or just have the misfortune of watching children’s TV shows), you may be familiar with the show “Bob the Builder.” Bob is a positive little man with serious intentions about building and fixing things. Prior to taking on any given task, he loudly asks himself and his team, “Can we fix it?” To which his team responds, “Yes we can!” Now, compare this approach with that of the Little Engine Who Could, who’s oft repeated success phrase was, “I think I can, I think I can…” In a nutshell, the research we’re about to discuss wanted to know which approach works best.

Researchers tested these two different motivational approaches first by telling study participants to either spend a minute wondering whether they would complete a task or telling themselves they would. The participants showed more success on an anagram task (rearranging words to create different words) when they asked themselves whether they would complete it than when they told themselves they would.

In another experiment, students were asked to write two seemingly unrelated sentences, starting with either “I Will” or “Will I,” and then work on the same anagram task. Participants did better when they wrote, “Will I” even though they had no idea that the word writing related to the anagram task. A final experiment added the dimension of having participants complete a test designed to gauge motivation levels. Again, the participants who asked themselves whether they would complete the task did better on the task, and scored significantly higher on the motivation test.

In other words, by asking themselves a question, people were more likely to build their own motivation than if they simply told themselves they’d get it done.

The takeaway for us: that little voice has a point, sort of. Telling ourselves that we can achieve a goal may not get us very far. Asking ourselves, on the other hand, can bear significant fruit, indeed. Retool your self-talk to focus on the questions instead of presupposing answers, and allow your mind to build motivation around the questions.

A short-cut: just remember the battle cry of Bob the Builder.

]]>https://neuronarrative.wordpress.com/2010/06/07/ask-dont-tell-and-get-it-done/feed/5David DiSalvoBobtheBuilderEverything We Knew About Human Vision is Wrong: Author Mark Changizi Tells Us Whyhttps://neuronarrative.wordpress.com/2010/05/05/everything-we-knew-about-human-vision-is-wrong-author-mark-changizi-tells-us-why/
https://neuronarrative.wordpress.com/2010/05/05/everything-we-knew-about-human-vision-is-wrong-author-mark-changizi-tells-us-why/#commentsWed, 05 May 2010 18:47:03 +0000http://neuronarrative.wordpress.com/?p=3882Continue reading →]]>For theoretical neurobiologist and author Mark Changizi, “why” has always been more interesting than “how.” While many scientists focus on the mechanics of how we do what we do, his research aims to grasp the ultimate foundations underlying why we think, feel and see as we do. Guided by this philosophy, he has made important discoveries on why we see in color, why we see illusions, why we have forward-facing eyes, why letters are shaped as they are, why the brain is organized as it is, why animals have as many limbs and fingers as they do, and why the dictionary is organized as it is.

His latest book, The Vision Revolution, is a trenchant and insightful investigation into why humans see and interact with the world as we do. His findings are challenging and often surprising, and his witty, engaging style is accessible to a broad range of readers . He was generous enough to spend a few minutes with me recently to discuss his book and other topics.

NN: What originally led you to write a book about human vision in particular, instead of any of the other human evolutionary adaptive traits?

MC: Indeed, I don’t consider myself solely a vision scientist. I call myself a theoretical neurobiologist, more generally, and I have had a number of non-vision research directions, including, for example, the shape and evolution of the brain, and why animals have as many limbs and digits as they do. Some of these research directions were central parts of my first book, The Brain from 25,000 Feet.

I was led to a book on vision because that’s where my research led me, and so the question is, Why did I end up with quite a few research directions in vision?

As a theoretical neurobiologist, I try to find interesting phenomena that I can wrap my head around, with the hope of putting forth and testing rigorous and general explanatory hypotheses. That’s not easy, but there are a number of reasons why it’s easier for vision.

First, relative to other senses and/or behaviors, the amount of data we possess for vision is huge. There’s a century-sized pile of data, much of it not well explained, much less in a unifying manner.

Second, vision is theoretically approachable. You have a visual field, you see objects, and so on. We know how to at least begin thinking about the phenomenology. It’s more difficult for audition, and practically impossible for olfaction, where we have little idea how to even describe our perceptions. …forget about explaining anything!

And, third, for vision we have the best understanding of the underlying mechanisms.

My point is that, as a theorist struggles for phenomena he or she can crack, vision appears as a large attractive target compared with many other aspects of brain and behavior. One may end up attacking vision problems even if one isn’t excited by vision, merely because it’s juicy. (I am excited by it, though, especially to the extent that I can find exciting hypotheses.)

I was intrigued by the “mind reading” aspects of vision. In a nutshell, how does this work, and how do humans benefit from this ability?

Our color vision fundamentally relies upon the cones in our retina, and I argue in my research that color vision evolved in us primates for the purpose of sensing the emotions and states of those around us. We primates have an unusual kind of color vision – our cones sample the visible spectrum in a peculiar fashion – and I have shown that one needs that kind of peculiar color sense in order to pick up the color modulations that occur on our skin when we blush, blanch, redden with anger, and so on. Our funny primate variety of color vision turns out to be optimized for seeing the physiological modulations in the blood in the skin that underlies our primate color signals.

So, we evolved special mechanisms designed for sensing the emotions and states of others around us. That sounds a lot like the evolution of a “mind-reading” mechanism, which is why I (only half in jest) describe it that way.

You mention in the book that reading and writing are relatively recent advances in human development, and yet we take for granted that we “see” and understand words, as if our brains were simply meant to see and understand them. What’s really going on that allows us to make sense of symbols on a page—and why can we do this at all?

In talks I often show a drawing of a child reading a book titled “How to Somersault.” The “joke” is that most kids are able to read very early, often even before they can do stereotypical ape behaviors like somersaults and monkey bars. Sure, they comprehend speech much earlier, but they’re getting orders of magnitude more speech thrown at them than writing. Kids learn to read very early, and very well; and as adults we are ridiculously capable readers, and spend nearly all our day reading.

Aliens might be excused for thinking we evolved to read.

But the invention of writing is only thousands of years old. In addition, for most of us, our grandparents, great grandparents or great great grandparents didn’t read at all. Writing is much too recent for our brains to have evolved to have reading mechanisms.

How does our brain do it?

Is it because our visual system can become good at reading whatever we present to it? No. Kids would surely not be capable readers by around six if they were tasked to read bar codes or fractal patterns.

The solution is that culture made writing easy on the eye, by shaping letters to be what the eye likes. The idea that culture shapes our artifacts to be good for us is not new. What’s new here is a specific hypothesis for what writing should look like in order to be good for us.

To be easy on the eye, writing needs to “look like nature,” just what our illiterate visual systems are fantastically competent at processing. The trick of that research direction was making this “writing looks like nature” idea rigorous, and coming up with ways of testing it. I show that there are certain signature visual patterns found in nearly any natural environment with opaque objects strewn about, and that these signature patterns are found in human writing. In short, writing has evolved so that written words look like visual objects.

You say that there are several visual “tricks” that makes us anticipate the next moment, while ensuring that the next moment never comes (one of these tricks you call “representational momentum”). Explain a little bit about how this works, and how does this misperception affect us in our day-to-day lives?

When light hits our retina, what our brains would like to do is instantaneously generate a perception of what the world looks like. Alas, our brain can’t do this instantaneously. Our brains are slow. It takes around a tenth of a second for your perception to be built, and that’s a long time when you’re moving about. If you perceived the world the way it was when light hit your eye, you’d be having a tenth-of-a-second old view of the world.

Because of this, visual systems have evolved mechanisms to try to generate a perception not of the way the world was when light hit the eye, but generate a perception of the way the world will be by the time the perception occurs in a tenth of a second. By the time the perception is elicited, the anticipated future will have arisen, and the perception will be of the present. That is, in order to perceive the present (have perceptions at time t that are of the world at time t), our visual systems must anticipate the near-future.

These mechanisms are, I argue, up and running at all times, looking for all sorts of cues in the stimulus in an attempt to guess the way the world will change in the next moment.

And this is where “tricks” come in. If we can cotton on to the cues your visual system is looking for in its attempt to guess the near future, then we can concoct artificial visual stimuli having these cues, but make sure they do not change as they “should” in the next moment. That way, when you look at them, your brain will generate a perception of what “should” happen next, but it will now be wrong due to the mad, evil psychologist.

The classical geometrical illusions are one of many classes of illusion that can be explained in this way. An example can be seen below, a variant of the Orbison illusion, where all the squares are actually the same, but appear quite different depending on where they lie within the radial display. Here is a link where I have written up a very short explanation of illusions like this:

If you were in charge of designing a new human vision system, what improvements would you make to the one we have now? What would you fix – and do you think there’s still evolutionary “room” left for human vision to evolve?

If we were still living out in nature as we Homo sapiens were for nearly all of our evolutionary history, then I’d be skeptical about any attempt to improve us. The most brilliant engineering masterpieces in the universe are found in biology, and my guess would typically be that, unless one has a very strong argument otherwise, we’re not smart enough to make any improvement.

But, of course, we’re no longer living in the kinds of environments where we evolved, and the biology may no longer be the “right” kind. In particular, I argue in the book that our forward-facing eyes are like a fish out of water. Forward-facing eyes are, I argue, the optimal eye design for large animals living in forested habitats; in those circumstances that eye design allows the animal to see the most. But we’re no longer living in cluttered habitats. Our world is now filled not with leaves, but with trash cans, pillars, and cars. In such circumstances sideways-facing eyes see the most, and animals in such environments accordingly have sideways-facing eyes. In a million years I bet we’ll be fish-faced.

One of the perennial questions in philosophy is: do we see things as they really are, or perceive them as we think they are? Given your work on human vision, what’s your take on this?

Let me give you three examples from the book that help us ponder these philosophical issues.

First consider illusions like those I discussed above. One often feels as if what we see is due to some kind of direct “reading” of the real physical world. But our brain can’t just passively react to the incoming stream of visual information, lest it have an old perception of the world. Instead, it must actively generate a guess about the near future, which helps drive home that our perception is always an internal concoction by your brain. In fact, most of the input to your visual system is feedback from that very visual system.

Second, consider forward-facing eyes and binocular vision. When we see with two eyes in the same direction, we have one unified visual perception. We have what feels like a single viewpoint, one that is emanating roughly from a point between our two eyes. Furthermore, our single viewpoint is always filled with two copies of the world that you hardly ever notice. When you fixate on something out in front of you, then objects nearer and farther split into two perceptual copies, each rendered as transparent in your perception.

This allows you to see objects, and to see beyond them. For example, you can see your own nose from opposite sides at all times, but it is rendered as partially transparent and so does not block your view of the world beyond. The more one analyzes the phenomenology of binocular vision, the stranger it seems. But it doesn’t feel strange, because these are perceptual facets that our brain knows how to interpret. They are needed as part of your unified view of the world in order to incorporate the fact that it is really built out of two views of the world. Although, in a sense, you are perceiving fictions, they are fictions that allow you to more veridically see the world.

And, lastly, consider color vision. This is a case that helps us better understand that it is not so much whether you see the world as it is, but how much of the world’s reality your are privy to seeing. Colors are primarily about the underlying emotions and states of those around us, as seen through the window of skin, and the physiological changes in the blood. The spectrum of skin is complicated, but it varies over two dimensions that matter most for sensing the states of others, the concentration and oxygenation of skin.

The question is, what does the concentration and oxygenation of blood in the skin of others “truly” look like? Or, what do the emotions those blood variables signify “truly” look like? The interesting thing here is that these blood dimensions and these emotions are “really there”, but there is little sense to what their “real look” might be. Colors serve the role of what they look like, but does red really look like oxygenated blood or really look like anger? I’m not sure this is a sensible question. What matters is that that qualitative perceptual state is given a meaning or association to us, and so serves its purpose.

What’s your next project? Any new books in the works that we should be looking out for soon?

I just recently finished my new book, tentatively titled Harnessed: How Language and Music Mimicked Nature and Transformed Ape to Man. Remember the child reading the book titled “How to Somersault”? If that kid can read so early because writing has culturally evolved to shape writing to look like nature, couldn’t it be that speech has culturally evolved (perhaps over hundreds of thousands of years, rather than just several thousand years) to sound like nature? Could it be that speech has shaped itself to sound like the natural events that our auditory systems evolved via natural selection to be fantastic at processing? And, similarly, could it be that music has culturally evolved over time to sound like some other auditory aspect of nature that taps into ancient auditory mechanisms of ours, evocative ones? The short story of the book is, Yes. And, in particular, I argue that speech sounds like solid-object physical events, whereas music sounds like people moving about.